Technical Field
[0001] The present invention relates to a delivery container for a drone and more particularly
relates to a delivery container for a drone that can prevent a load to be delivered
from getting damaged or wet and can easily and more reliably protect the load.
Background Art
[0002] In recent years, so-called drones that use air routes have been attracting attention
as a means of delivering loads. By using drones, relatively small (light weight) loads
can be rapidly delivered to locations where delivery using land routes and water routes
is difficult. When delivering a load using a drone, if a cushioning material and the
load are packed and delivered together in corrugated cardboard, the load may be damaged
by impact from the corrugated cardboard falling. Further, corrugated cardboard cannot
sufficiently prevent the load stored therein from getting wet during delivery in rainy
weather.
[0003] Thus, a package using an outer container such as corrugated cardboard and an inner
packaging material has been proposed (see Patent Document 1). In the package proposed
in Patent Document 1, the inner packaging material storing the load is held in a suspended
state inside the outer container by a plurality of elastic towing ropes. Then, the
inner packaging material storing the load is closed and the inside thereof is evacuated.
Even if the load is held in a suspended state inside the outer container, when the
outer container falls and is greatly deformed or damaged, the impact force also acts
on the load, and so the load cannot be sufficiently protected. In addition, suspending
the load in this way takes a lot of time and effort. Further, even if the inside of
the inner packaging material can be evacuated to protect the load from moisture, it
takes time and effort to evacuate the inside. Thus, there is room for improvement
in more easily and reliably protecting the load.
Citation List
Patent Literature
Summary of Invention
Technical Problem
[0005] An object of the present invention is to provide a delivery container for a drone
that can prevent a load to be delivered from getting damaged or wet and can easily
and more reliably protect the load.
Solution to Problem
[0006] To achieve the object described above, a delivery container for a drone according
to the present invention is a delivery container for a drone including an outer container
held by a drone and a cushioning portion stored inside the outer container. The outer
container is formed of an elastic material and is watertight, and a load opening of
the outer container that opens and closes is designed to be watertight. The cushioning
portion is interposed between a load stored inside the outer container and the outer
container to hold the load within a predetermined range inside the outer container.
Advantageous Effects of Invention
[0007] According to the present invention, the load is protected from the impact force by
a cushioning effect of the outer container formed of an elastic material and a cushioning
effect of the cushioning portion stored inside the outer container. Further, since
the outer container is watertight and the load opening is also designed to be watertight,
it is possible to prevent the load from getting wet even during delivery in rainy
weather. Even with this simple configuration, it is possible to more reliably protect
the load.
Brief Description of Drawings
[0008]
FIG. 1 is an explanatory diagram illustrating an embodiment of a delivery container
for a drone in a side view.
FIG. 2 is an explanatory diagram illustrating the delivery container of FIG. 1 in
a cross-sectional view.
FIG. 3 is an explanatory diagram illustrating a state in which a load opening of FIG.
1 is open.
FIG. 4 is an explanatory diagram illustrating a modified example of a cushioning portion
of FIG. 1.
FIG. 5 is an explanatory diagram illustrating a state in which the load stored in
the delivery container of FIG. 1 is delivered by a drone.
FIG. 6 is an explanatory diagram illustrating another embodiment of the delivery container
in a side view.
FIG. 7 is an explanatory diagram illustrating the delivery container of FIG. 6 in
a cross-sectional view.
FIG. 8 is an explanatory diagram illustrating a modified example of the cushioning
portion of FIG. 6.
FIG. 9 is an explanatory diagram illustrating another embodiment of the delivery container
in a side view.
FIG. 10 is an explanatory diagram illustrating the delivery container of FIG. 9 in
a cross-sectional view.
FIG. 11 is an explanatory diagram illustrating a modified example of the cushioning
portion of FIG. 9.
FIG. 12 is an explanatory diagram illustrating another embodiment of the delivery
container in a side view.
FIG. 13 is an explanatory diagram illustrating the delivery container of FIG. 12 in
a cross-sectional view.
FIG. 14 illustrates a modified example of the cushioning portion of FIG. 12. FIG.
14(A) is an explanatory diagram illustrating a state in which two independent air
chambers are combined. FIG. 14(B) is an explanatory diagram illustrating each air
chamber independently.
FIG. 15 is an explanatory diagram illustrating another embodiment of the delivery
container in a side view.
FIG. 16 is an explanatory diagram illustrating the delivery container of FIG. 15 in
a cross-sectional view.
FIG. 17 is an explanatory diagram illustrating a modified example of the cushioning
portion of FIG. 15.
FIG. 18 is an enlarged view illustrating a modified example of the outer surface of
the outer container.
Description of Embodiments
[0009] A delivery container for a drone according to embodiments of the present invention
will be described below with reference to the drawing.
[0010] A delivery container for a drone 1 according to an embodiment illustrated in FIGS.
1 to 3 includes an outer container 2 and a cushioning portion 5 stored inside the
outer container 2. The outer container 2 is held by a drone D. The outer container
2 is formed of an elastic material and is watertight. Examples of the elastic material
forming the outer container 2 include various vulcanized rubbers, soft resins, and
elastomer, and the like. The outer container 2 may be formed of only an elastic material,
or may be formed of an elastic material in which a reinforcing wire such as a fiber
is embedded. An elastic material having a large number of gas bubbles may also be
used for the outer container 2.
[0011] Various shapes may be employed for the outer container 2. In this embodiment, the
outer container 2 having a cylindrical shape is used. The wall thickness of the outer
container 2 is, for example, approximately several mm or more and several cm or less.
[0012] The outer container 2 is provided with a load opening 3 for taking a load B to be
delivered in and out of the outer container 2. The load opening 3 that opens and closes
is designed to be watertight. In this embodiment, the load opening 3 is provided at
one end side of the shaft of the cylindrical outer container 2.
[0013] As a water stop portion 3a, the load opening 3 includes a fastener that is watertight
and extends along substantially the entire circumference in the circumferential direction
of the outer container 2 having a cylindrical shape, and the load opening 3 is opened
and closed by the fastener. In addition to fasteners that engage a pair of pieces,
various known fasteners such as surface fasteners can be designed to be watertight
and used as the water stop portion 3a.
[0014] The cushioning portion 5 is interposed between the load B stored inside the outer
container 2 and the outer container 2. Because the cushioning portion 5 is deformed
(elastic deformation), the load B is held within a predetermined range inside the
outer container 2. The predetermined range is a range in which the load B does not
come into direct contact with the outer container 2. Because the cushioning portion
5 is deformed, the load B is held while displacement with respect to the cushioning
portion 5 is suppressed. Further, since the cushioning portion 5 is pressed against
the inner surface of the outer container 2, the cushioning portion 5 is in a state
of being held while displacement with respect to the outer container 2 is suppressed.
Since the outer container 2 is pressed from the inside by the cushioning portion 5,
the outer container 2 is moderately strained to maintain a predetermined external
shape.
[0015] The cushioning portion 5 may be formed of a non-elastic material. However, in order
to obtain a more excellent cushioning effect, it is preferably formed of an elastic
material. Examples of the elastic material forming the cushioning portion 5 include
various vulcanized rubbers, soft resins, and elastomer, and the like. The cushioning
portion 5 may be formed of only an elastic material, or may be formed of an elastic
material in which a reinforcing wire such as a fiber is embedded. An elastic material
having a large number of gas bubbles may also be used for the cushioning portion 5.
[0016] The cushioning portion 5 preferably includes an air chamber 6 that is sealed in order
to obtain a more excellent cushioning effect. When the cushioning portion 5 includes
the air chamber 6, the cushioning portion 5 may also be formed of a non-elastic material.
[0017] The cushioning portion 5 is preferably disposed so as to cover the entire outer circumference
of the load B. When a partial range of the baggage B is made into an uncovered state
by the cushioning portion 5, a certain distance (for example, 5 cm or more) is ensured
between the partial range in the uncovered state and the inner surface of the outer
container 2.
[0018] In this embodiment, the cushioning portion 5 having a cylindrical body along the
inner circumferential surface of the outer container 2 is included. The air chamber
6 having a cylindrical shape is formed inside the cushioning portion 5. An air injection
inlet 7 is provided at an end portion of the cushioning portion 5 at the load opening
3 side. Air can be injected into and discharged from the air chamber 6 through the
air injection inlet 7. By adjusting the amount of air injected into the air chamber
6, the cushioning portion 5 is expanded appropriately.
[0019] In this embodiment, the cushioning portion 5 is integrated with the outer container
2 and disposed inside the outer container 2. Accordingly, before air is injected into
the air chamber 6 to expand the cushioning portion 5, the load B is disposed inside
the cylindrical cushioning portion 5, and then air is injected into the air chamber
6 and the cushioning portion 5 is expanded. In this way, the load B is held in the
predetermined range inside the outer container 2. Thereafter, the load opening 3 is
closed, and the operation of accommodating the load B in the delivery container 1
is completed.
[0020] As illustrated in FIG. 4, the cushioning portion 5 may be separated from the outer
container 2 so that the cushioning portion 5 can be put into and taken out of the
outer container 2. In the cushioning portion 5, the air chamber 6 is formed inside
the cushioning portion 5 having a flat plate shape. This flat plate-shaped cushioning
portion 5 wraps the load B and is formed into a cylindrical body, and then is stored
inside the outer container 2. Thereafter, air is injected into the air chamber 6 to
expand the cushioning portion 5, and the load B is held in a predetermined range inside
the outer container 2.
[0021] The delivery container 1 is used as follows when delivering the load B.
[0022] As illustrated in FIG. 5, the delivery container 1 in which the load B is stored
is held in a holding arm Da of the drone D flying by remote control or automatic control,
and is delivered by air from the delivery source to the destination. When the delivery
container 1 arrives at the destination, the holding by the holding arm Da is released,
the delivery container 1 is separated from the drone D, and the delivery is completed.
[0023] Even when the delivery container 1 falls from an unintended height when the holding
by the holding arm Da is released or during delivery, in the delivery container 1,
the outer container 2 formed of an elastic material and the cushioning portion 5 exhibit
the cushioning function. That is, by the cushioning effect of the outer container
2 and the cushioning effect of the cushioning portion 5, the load B is protected from
the impact force generated when dropped. When the cushioning portion 5 formed of an
elastic material or the cushioning portion 5 having the air chamber 6 is used, the
cushioning effect is further improved, which is more advantageous for protecting the
load B from the impact force.
[0024] Since the outer container 2 is watertight and the load opening 3 is also designed
to be watertight, moisture is prevented from entering the inside of the outer container
2. Thus, even in a case of delivery in rainy weather or the like, the use of this
delivery container 1 prevents the load B from getting wet. As described above, while
the delivery container 1 has a simple configuration, it is possible to more reliably
protect the load B.
[0025] When the load B is displaced inside the outer container 2 during delivery, the balance
of the drone D is lost and the flight becomes unstable. However, in this delivery
container 1, the load B is held in a state where displacement with respect to the
cushioning portion 5 is suppressed, and the cushioning portion 5 is held in a state
where displacement with respect to the outer container 2 is suppressed. Thus, the
displacement of the load B is unlikely to occur inside the outer container 2 during
delivery, which is advantageous for the stable flight of the drone D. Further, since
the outer container 2 is pressed from the inside by the cushioning portion 5 to maintain
a predetermined external shape, the external shape of the outer container 2 does not
easily change during delivery. From this perspective, it is advantageous for the stable
flight of the drone D.
[0026] When the cushioning portion 5 has one air chamber 6, the cushioning effect of the
cushioning portion 5 is reduced when the air chamber 6 is damaged. Thus, it is preferable
that the cushioning portion 5 includes a plurality of independent air chambers 6.
[0027] In the embodiment of the delivery container 1 illustrated in FIGS. 6 to 7, the cushioning
portion 5 has a plurality of independent air chambers 6 (6A, 6B, 6C, 6D, 6E, 6F, 6G,
and 6H). Each of the air chambers 6 has a columnar shape, and these columnar air chambers
6 are arranged side by side in a cylindrical shape, and the cushioning portion 5 is
formed in a cylindrical body. The cushioning portion 5 is integrated with the outer
container 2 and disposed inside the outer container 2. The load B is held inside the
cushioning portion 5 in the cylindrical body. The number of air chambers 6 is determined
as appropriate. According to this embodiment, even when one air chamber 6 is damaged,
the cushioning effect can be obtained by the remaining healthy air chamber 6.
[0028] As illustrated in FIG. 8, this cushioning portion 5 may also be separated from the
outer container 2 so that the cushioning portion 5 can be put into and taken out of
the outer container 2. In this cushioning portion 5, a plurality of columnar independent
air chambers 6 (6A, 6B, 6C, 6D, 6E, 6F, 6G, and 6H) are formed side by side inside
the cushioning portion 5 having a flat plate shape. This cushioning portion 5 wraps
the load B and is formed into a cylindrical body, and then is stored inside the outer
container 2. Thereafter, air is injected into each air chamber 6 to expand the cushioning
portion 5, and the load B is held in a predetermined range inside the outer container
2.
[0029] In the embodiment of the delivery container 1 illustrated in FIGS. 9 to 10, the cushioning
portion 5 has a plurality of independent air chambers 6 (6A, 6B, 6C, and 6D). Each
of the air chambers 6 is annular, and these annular air chambers 6 are arranged side
by side in the width direction, and the cushioning portion 5 is formed in a cylindrical
body. The cushioning portion 5 is integrated with the outer container 2 and disposed
inside the outer container 2. The load B is held inside the cushioning portion 5 in
the cylindrical body. The number of air chambers 6 is determined as appropriate. According
to this embodiment, even when one air chamber 6 is damaged, the cushioning effect
can be obtained by the remaining healthy air chamber 6.
[0030] As illustrated in FIG. 11, this cushioning portion 5 may also be separated from the
outer container 2 so that the cushioning portion 5 can be put into and taken out of
the outer container 2. A plurality of independent annular air chambers 6 (6A, 6B,
6C, and 6D) are arranged side by side, and the cushioning portion 5 is formed in a
cylindrical body. The load B is inserted into each annular air chamber 6 (in a state
where air is slightly injected), and then this cushioning portion 5 is stored inside
the outer container 2. Thereafter, air is injected into each air chamber 6 to expand
the cushioning portion 5, and the load B is held in a predetermined range inside the
outer container 2.
[0031] In the embodiment of the delivery container 1 illustrated in FIGS. 12 to 13, the
cushioning portion 5 has a plurality of independent air chambers 6 (6A and 6B). Each
of the air chambers 6 has a columnar shape, and these columnar air chambers 6 are
arranged side by side in a spiral shape, and the cushioning portion 5 is formed in
a cylindrical body. The cushioning portion 5 is integrated with the outer container
2 and disposed inside the outer container 2. The load B is held inside the cushioning
portion 5 in the cylindrical body. The number of air chambers 6 is determined as appropriate.
According to this embodiment, even when one air chamber 6 is damaged, the cushioning
effect can be obtained by the remaining healthy air chamber 6.
[0032] As illustrated in FIG. 14, this cushioning portion 5 may also be separated from the
outer container 2 so that the cushioning portion 5 can be put into and taken out of
the outer container 2. A plurality of independent columnar air chambers 6 (6A and
6B) are arranged side by side in a spiral shape, and the cushioning portion 5 is formed
in a cylindrical body. FIG. 14A illustrates a state in which two spiral air chambers
6A and 6B are combined side by side, and FIG. 14B illustrates a state in which the
air chambers 6A and 6B are separated. The load B is inserted into each spiral air
chamber 6 (in a state where air is slightly injected), and then this cushioning portion
5 is stored inside the outer container 2. Thereafter, air is injected into each air
chamber 6 to expand the cushioning portion 5, and the load B is held in a predetermined
range inside the outer container 2.
[0033] In the embodiment of the delivery container 1 illustrated in FIGS. 15 to 16, the
cushioning portion 5 includes a large number of linear members 5b formed of elastic
members protruding from the inner surface side of the outer container 2 and is formed
in a cylindrical body. These linear members 5b are disposed projecting on the surface
of a base 5a having a flat plate shape. Inside the cushioning portion 5 in the cylindrical
body, the load B is held in a state of being supported by a large number of elastic
linear members 5b. For the specification of the linear members 5b (length, thickness,
distribution density, and the like), a test or simulation of the cushioning effect
of the cushioning portion 5 is performed in advance to determine the appropriate specification.
[0034] In this embodiment, the cushioning portion 5 is integrated with the outer container
2 and disposed inside the outer container 2. Accordingly, when the load B is disposed
inside the cushioning portion 5 having the cylindrical body, the load B is held within
a predetermined range inside the outer container 2. Thereafter, the load opening 3
is closed, and the operation of accommodating the load B in the delivery container
1 is completed.
[0035] As illustrated in FIG. 17, this cushioning portion 5 may also be separated from the
outer container 2 so that the cushioning portion 5 can be put into and taken out of
the outer container 2. In this cushioning portion 5, a large number of linear members
5b formed of an elastic material projecting from one surface of the base 5a having
a flat plate shape. The cushioning portion 5 wraps the load B and is formed into a
cylindrical body and then is stored inside the outer container 2, so that the load
B is held within a predetermined range inside the outer container 2.
[0036] Various shapes can be employed for the outer container 2, but in order to reduce
the air resistance received during delivery, for example, the outer container 2 may
be formed in a simple spherical shape or an elliptical spherical shape such as a rugby
ball to have a shape having a streamlined surface. Further, the outer container 2
preferably has a shape having as few corners as possible, and even in a case of a
cylindrical shape, the corners preferably have an arc shape (round shape).
[0037] As illustrated in FIG. 18, a large number of dimples 4 may be scattered on the outer
surface of the outer container 2 like a golf ball. These dimples 4 make the flow of
air around the outer surface of the outer container 2 appropriately turbulent during
delivery. Along with this, the air resistance received by the outer container 2 is
reduced, and an additional load acting on the drone D during delivery can be reduced.
For the specification of the dimple 4 (size, shape, distribution density, and the
like), an air resistance test or simulation of the outer container 2 is performed
in advance to determine the appropriate specification.
Reference Signs List
[0038]
1 Delivery container
2 Outer container
3 Load opening
3a Water stop portion
4 Dimple
5 Cushioning portion
5a Base
5b Linear member
6 (6A, 6B, 6C, 6D, 6E, 6F, 6G, 6H) Air chamber
7 Air injection inlet
B Load
D Drone
Da Holding arm
1. A delivery container for a drone, comprising:
an outer container held by a drone; and
a cushioning portion stored inside the outer container,
the outer container being formed of an elastic material and being watertight, and
a load opening of the outer container that opens and closes being designed to be watertight,
and
the cushioning portion being interposed between a load stored inside the outer container
and the outer container to hold the load within a predetermined range inside the outer
container.
2. The delivery container for a drone according to claim 1, wherein the cushioning portion
is integrated with the outer container and disposed inside the outer container.
3. The delivery container for a drone according to claim 1, wherein the cushioning portion
can be separated from the outer container and taken in and out of the outer container.
4. The delivery container for a drone according to any one of claims 1 to 3, wherein
the cushioning portion is formed of an elastic material.
5. The delivery container for a drone according to any one of claims 1 to 4, wherein
the cushioning portion comprises an air chamber that is sealed.
6. The delivery container for a drone according to claim 5, wherein a plurality of the
air chambers are provided with each being independent.
7. The delivery container for a drone according to claim 6, wherein each of the air chambers
has a columnar shape, and the air chambers each having the columnar shape are arranged
side by side in a cylindrical shape and the cushioning portion is formed in a cylindrical
body, and the load is held inside the cylindrical body.
8. The delivery container for a drone according to claim 6, wherein each of the air chambers
is annular, and the air chambers each being annular are arranged side by side in a
width direction and the cushioning portion is formed in a cylindrical body, and the
load is held inside the cylindrical body.
9. The delivery container for a drone according to claim 6, wherein each of the air chambers
has a columnar shape, and the air chambers each having the columnar shape are arranged
side by side in a spiral shape and the cushioning portion is formed in a cylindrical
body, and the load is held inside the cylindrical body.
10. The delivery container for a drone according to claim 4, wherein the cushioning portion
comprises a large number of linear members protruding from an inner surface side of
the outer container.
11. The delivery container for a drone according to any one of claims 1 to 10, wherein
a large number of dimples are scattered on an outer surface of the outer container.